Selective temperature control system

ABSTRACT

A method and apparatus is disclosed for determining the temperature to which a thermistor is exposed. A capacitor is charged through a reference resistor and the length of time required to charge the capacitor to a predetermined level is measured to obtain a reference charge time. The capacitor is discharged, and then charged through the thermistor and the length of time required to charge the capacitor to the predetermined level through the thermistor is measured to obtain a temperature charge time. The temperature to which the thermistor is exposed is determined by computing the difference between the reference charge time and the temperature charge time divided by the sum of the times.

This .Iadd.application is a continuation of application Ser. No.939,551, filed 12/9/86, and now abandoned, which is a reissue ofapplication Ser. No. 317,333, filed 11/2/81, now U.S. Pat. No.4,488,823, which .Iaddend.is a division of application Ser. No. 108,694,filed Dec. 31, 1979, now U.S. Pat. No. 4,315,413, issued Feb. 16, 1982.

BACKGROUND OF THE INVENTION

The present invention relates to a selective temperature control systemfor use in a space cooling device, such as a room air conditioner, inwhich the compressor energization and the fan speed are adjustedautomatically in response to the difference between the ambienttemperature and a set point temperature.

In many air conditioning systems, the compressor motor and evaporatorfan motor are variable in speed by using a user-set controlpotentiometer and a feedback circuit which senses the motor speeds. Suchsystems are responsive to temperature sensors or thermostats to vary thecompressor motor speed and the evaporator fan speed.

In some prior art systems, to protect the evaporator coils from freezingand also to sense the ambient temperature, a vapor bulb thermostat hasbeen mounted on a plastic block which in turn is mounted on theevaporator coils so as to sense both the evaporator temperature and theambient temperature. However, such attempts to sense both temperaturesusing only one sensor results in large temperature swings within thecooled room because of the mixing of the evaporator and ambienttemperatures.

Some air conditioning controls also employ the use of a compressorlockout, which is designed to prevent the compressor from short cyclingand from locking up. Often this is achieved by the use of a timer whichinsures that the compressor will remain off for a predetermined amountof time. Other systems employ the use of a percentage timer whichinsures that the compressor is off for a fixed percentage of time withina complete compressor cycle.

SUMMARY OF THE INVENTION

In accordance with the present invention, a selective temperaturecontrol system for a room air conditioner utilizes two separatetemperature sensors, such as thermistors. An evaporator temperaturesensor monitors the temperature of the evaporator and, in the event thatthe temperature of the evaporator falls below a pre-determined limit,the control system turns off the compressor to prevent significant frostbuildup on the evaporator. An ambient temperature sensor is located soas to sense the average temperature of the room, rather than a mixtureof the evaporator and the ambient temperatures. Temperature swingswithin the room are minimized because the temperature of the evaporatordoes not affect the ambient temperature sensor.

The temperature control circuit includes a microcomputer chip. Thisallows the use of a minimum number of hardwired components, therebyreducing space requirements. In addition, LED indicators are used toindicate the status of the air conditioning control.

The ambient and evaporator temperatures are determined by alinearization computation which utilizes a reference resistor. Acapacitor is sequentially charged through the reference resistor, theambient sensor and the evaporator sensor by a voltage source. The timerequired for each to charge the capacitor to a particular voltage ismeasured and the charging times are used to calculate the ambient andevaporator temperatures.

In the present invention, the fan speed is varied in response to thedifference between the ambient temperature and a set point temperaturewhich is determined by the position of a slide switch. The control logicof the microcomputer scans the slide switch to determine which switchposition has been selected by the user. The control logic converts theslide switch position into a value proportional to the desired set pointtemperature to determine the difference between the ambient and the setpoint temperature.

Other features of the invention will be apparent from the followingdescription and from the drawings. While an illustrative embodiment ofthe invention is shown in the drawings and will be described in detailherein, the invention is susceptible of embodiment in many forms and itshould be understood that the present disclosure is to be considered asan exemplification of the principles of the invention and it is notintended to limit the invention to the embodiment illustrated.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of an air conditioner and a block diagramof the temperature control system therefor;

FIG. 2 is an enlarged fragemtnary elevational view of the airconditioner showing the location of the control panel and the evaporatorsensor;

FIG. 3 is an enlarged fragmentary side elevational view of a portion ofthe air conditioner showing the ambient sensor and the temperaturecontrol circuit board.

FIGS. 4a and 4b are diagrams of the transfer function of the AUTO modeof the present invention.

FIG. 5 is a schematic diagram of the control logic shown in block formin FIG. 1.

FIG. 6 is a schematic diagram of the compressor and fan triac circuitsshown in block form in FIG. 1.

FIG. 7 illustrates waveform diagrams (not to scale) of the sensorresistance value detection process.

FIGS. 8a, 8b, 8c and 8d comprise a single flowchart, when joined alongsimilarly lettered lines, of the control program contained in thecontrol logic.

FIGS. 9a and 9b comprise a single flowchart, when joined along similarlylettered lines, of the temperature determining program contained in thecontrol logic.

DESCRIPTION OF THE PREFERRED EMBODIMENT

Turning to FIG. 1, a space cooling device in the form of a conventionalroom air conditioning system 20 is illustrated in conjunction with thetemperature control system. The air conditioning unit 20 includes achassis 22 upon which the various components of the air conditioningunit 20 are mounted. Air is cooled as a result of being passed in heatexchange relationship with an evaporator 24 and is forced by a fan 26through a discharge duct and an outlet grill (not shown) into the room.The cooling apparatus includes a conventional compressor 32, condenser34 and a heat sink 36 interconnected through tubing to the evaporator 24to effect the flow of refrigerant thereto.

As seen in FIGS. 2 and 3, a control panel 40, which is located adjacentto the evaporator 24, includes a plurality of switches 42-47 by whichthe air conditioner is controlled. The control panel 40 also mounts athermostat slide switch 50 by which the user can select the set point,or desired temperature, of the cooled room. An ambient temperaturesensor 51, such as a thermistor, is mounted on the upper portion of acircuit board 58 behind the control panel 40 to be exposed to atemperature which is representative of the average temperature of theroom. This location is preferred because the ambient sensor 51 islocated sufficiently distant from the evaporator, condenser andcompressor so as not to be influenced by their temperatures which wouldprovide a false reading of the ambient temperature. Further, mountingthe ambient sensor 51 on the circuit board 58 minimizes wiringdifficulties and positions the sensor 51 near the ambient air.

Associated with the switches 42-47 are a plurality of visual indicatorsin the form of light emitting diodes, or LED's 52-57, which serve toindicate when a particular switch has been depressed. Additionally, anON/OFF switch 60 is mounted on the control panel 40 to controlenergization of the various components of the air conditioning unit 20.

Mounted directly on the return bend of the evaporator coil 24 by meansof a metal strap 61 or other suitable means is an evaporator temperaturesensor 62, which may also be a thermistor and which monitors thetemperature of the evaporator coils.

Referring again to FIG. 1, there is illustrated in block diagram formthe various electrical components which operate the air conditioningunit 20. A memory 64 and a compressor and fan timer 65 operate inconjunction with control logic 66. Other inputs to the control logic 66include the ambient temperature sensor 51, the evaporator temperaturesensor 62, the control panel 40 and the thermostat slide switch 50.Outputs from the control logic 66 include two compressor triacs 73 and74, three fan triacs 70, 71 and 72, and the LED's 52-57.

Referring also to FIG. 5, the memory 64, the timer 65 and the controllogic 66 shown in FIG. 1 may be implemented using digital logic orthrough the use of a microcomputer as shown in FIG. 5. In the preferredembodiment, shown in detail in FIG. 5, a single chip microcomputer 68 isused to implement the circuitry shown within dashed lines in FIG. 1. Inthe illustrated embodiment, microcomputer 68 is implemented by using anAmerican Microsystems, Inc. S2000 Microcomputer which has a 1024 word by8-bit Read-Only-Memory (ROM) 151, a 64 word by 4-bitRandom-Access-Memory (RAM) 150 substantially corresponding to the memory64 of FIG. 1, a switch interface and a seconds timer (not shown) for the60 Hz. power line which powers the air conditioner and associateddrivers. The control logic 66 is implemented in the ROM 151, which alsocontains the control program and contants for the system. Variousintermediate and final values are stored in registers in the RAM 150.Although, for purposes of clarity the intermediate and final values areillustrated as being stored in separate and distinct registers in theRAM 150, it is to be understood that a single register may hold morethan one value over the course of a program execution.

Referring to FIGS. 1, 2 and 3, the operation of the air conditioningcontrol will be described in general terms with particularizations to bemade in subsequent parts of this specification.

Once the air conditioning unit 20 has been energized by depressing theON/OFF switch 60, the user can select a variety of control functions bydepressing one or more of the switches 42-47 located on the controlpanel 40. If the user depresses the "FAN ONLY" button 44 in conjunctionwith the high speed (or "HI") button 43, or the medium speed ("MED")button 45 or the low speed ("LOW") button 47, the fan 26 is energized atthe particular speed selected while the compressor 32 remains off.Constant fan speed with cooling can be accomplished by depressing anyone of the "HI" 43, "MED" 45 or "LOW" 47 buttons. Use of one of thethree buttons and no other button being depressed results in the fan 26being set to a selected speed while the compressor 32 is energized.

Referring also to FIGS. 4a and 4b, the transfer functions for thecompressor 32 and fan 26 when the "AUTO" button 42 alone is depressedare illustrated. The compressor 32 is energized if the differencebetween the ambient temperature and the set point temperature, or T_(D),is greater than +2° F. If T_(D) is less than -2° F., the compressor isturned off. If T_(D) is greater than -2° F. but less than +2° F., thecompressor is either on or off depending upon whether the compressor wason or off before entering the interval between -2° F. and +2° F. Ingeneral, if the compressor was off before entering the interval, it willremain off until T_(D) equals +2° F. and if on before entering theinterval, will remain on until T_(D) equals -2° F.

In the "AUTO" mode the fan speed also varies as a function of thevariable T_(D). In general, the fan is set to high speed when T_(D) isgreater than approximately 3+ F. and is set to low speed when T_(D) isless than approximately 0° F. In the range from 0° F. to 3° F. the fanspeed is set to medium. The microcomputer 68 provides a slight amount ofhysteresis (approximately 0.5° F. centered at the switching points) toobtain noise immunity; therefore the fan switches speeds approximately0.25° F. on either side of the switching points.

Use of the "AUTO" button 42 along with the "FAN ONLY" button 44 resultsin the compressor 32 being turned off while the fan 26 alone continuesto cycle in the "AUTO" mode; i.e. the fan speed will vary according tothe variable T_(D).

Use of the "POWER SAVER" button 46 in conjunction with the "AUTO" button42 results in compressor 32 following the AUTO transfer function whilethe evaporator fan 26 remains energized at low speed for two minutes bythe timer 65 after the compressor 32 cycles off. This feature is used totake advantage of the extra cooling capacity which remains in theevaporator 24 after the compressor 32 cycles off. Furthermore, as shownby the dotted line 4b-1 of FIG. 4b, the "POWER SAVER" mode prevents thefan from turning back on until T_(D) has reached +2° F., at which pointthe fan speed is set to medium.

Selection of one of the buttons 42-47 will light its corresponding LEDvisual indicator; e.g. selection of button 42 will light LED 52. Thisprovides a ready indication of the status of the air conditioning unit20 at any time. The buttons 42-47 are of suitable construction and inthe preferred embodiment are small excursion pressure sensitive contactswitches which have little or no tactile feedback.

The compressor is prevented by the timer 65 from startup until afterapproximately two minutes has elapsed from the time the compressor 32cycles off. This is used to prevent short cycling and to prevent lockupof the compressor 32. Microcomputer 68 also monitors the evaporatortemperature sensor 62 and shuts off the compressor 32 in the event thatthe evaporator temperature falls below a predetermined limit. Thisfeature is included to prevent significant frost buildup on theevaporator 24.

In FIGS. 5 and 6, the circuit of the temperature control system, shownin block form in FIG. 1, is illustrated in detail. Resistor R1 andcapacitor C1, FIG. 5, connected in series between a voltage supplysource V_(SS) and a source of ground potential GND, form a timingcircuit for a signal from an internal clock oscillator of themicrocomputer 68. This clock signal, derived at the junction of R1 andC1, is inputted on line 100 to the clock or CLK input of themicrocomputer 68. A capacitor C2 and a diode D1 connected in seriesbetween V_(SS) and ground potential GND provide a power-on-resetfunction with the capacitor C2 holding the computer reset line lowmomentarily to allow time for the power supply to stabilize. The diodeD1 pulls the reset line low in case of a power failure, restoring themicrocomputer to its initial state. The power-on-reset signal istransmitted over a line 102 to the power-on-reset (POR) input to themicrocomputer 68. The voltage supply V_(SS) is inputted to themicrocomputer 68 over line 104.

Display output lines A0, A4, A5, A10, A11 and A12 sink current throughLED's 52-57 when the corresponding line is pulled low. Resistors R6-R11connected in series between the LED's 52-57 and their corresponding "A"lines limit the current through the LED's. In addition, the output linesA10, A11 and A12 also turn on the fan triacs 70, 71 and 72 illustratedin FIG. 6. The output line A9 drives the compressor 32 through aresistor R5 in a manner to be hereinafter described.

In the illustrated embodiment, the slide switch 50 consists of eightcontacts 50a-50h each individually connected to an associated, differentD line, and an output contact 50k connected to a movable wiper 50m whichis manually moved by the user into contact with one of the inputs50a-50h.

The touch panel switches 42-47 and the thermostat slide switch 50positions are scanned by eight sensing outputs D0-D7 and two switch datainputs K2 and K4. Sequentially, each "D" line is sent a signal by thecontrol logic 66, while the other "D" lines are de-energized. The twoswitch data inputs, K2 and K4 are inputtted while each "D" line ispulled high. If K2 detects a signal, this indicates that the touch panelswitch 42-47 corresponding to the enerigzed "D" line is depressed.Similarly, input K4 connected to the output 50k of slide switch 50,determines the slide switch position and the control logic 66 internallyconverts the slide switch position into a value proportional to thedesired temperature set point. The slide switch position is then storedby the control logic 66 in a switch state register (denoted SW.ST.) inthe RAM 150, and the contents of the register are used to access amemory location in the ROM 151 which contains the corresponding setpoint value. This set point value is written over the contents of theSW.ST. register for use in later calculation.

Resistors R12 and R13, connected between the supply voltage V_(SS) andrespectively control panel 40 and slide switch 50, pull the K2 and K4input voltages down so that they will appear low when a button or switchis open. The touch panel is "debounced" by the control logic 66; a touchpanel switch must be pushed for four consecutive microcomputer cycles(approximately 250 milliseconds) or it will be ignored. Resistors R3 andR4 connected between voltage supply V_(SS) and GND provide a referencevoltage at their junction which is inputted to the K_(REF) input to themicrocomputer 68 over a line 106. This reference voltage provides abasis for determining the state of input signals to K2 and K4 inputterminals. Two voltage supply inputs V_(DD) and V_(GG), a ROM sourcecontrol "ROMS" and a Run/Wait control "RUN" are all connected to groundpotential GND.

Temperature information is inputted to the microcomputer 68 at an inputK8 over a line 108. The diodes D8, D9 and D10 are connected to theoutput lines A7, A6 and A8 in series with a reference resistor R14, theambient temperature sensor 51 and the evaporator temperature sensor 62,respectively. The three lines are connected to voltage supply V_(SS)through the capacitor C5 and to the input line K8 through the line 108.

Referring to FIG. 5 and the timing diagram of FIG. 7, the timingcapacitor C5 is first discharged by the input K8 with the output linesA6, A7 and A8 de-energized to eliminate any residual charge present onC5. Then the output line A7 comprising a first charging means isenergized, charging the capacitor C5 through the reference resistor R14which is of a known value. The diodes D9 and D10 prevent current flowthrough the other two resistors, sensors 51 and 62. The time before theinput K8 reaches a particular voltage is measured by timing means in theform of the control logic 66 in terms of microcomputer timing cycles(this voltage is equal to the voltage appearing at the K_(REF) input, orabout 3 volts). This time, t_(REF), denoted the reference charge timeand as shown in FIG. 7, is proportional to the resistance of R14 and isstored in a register in the RAM 150. The capacitor C5 is then dischargedby the input K8 and in a similar manner output line A6 is energized andthe time before the input K8 reaches the particular voltage is measuredto obtain an ambient thermistor charge time, t_(AMR). The process isrepeated by the output line A8 to measure the evaporator thermistorcharge time, t_(EVAP). The output lines A6-A8 together comprisesequential charging means in that the capacitor C5 is first chargedthrough the reference resistor R14, and is then charged through theambient thermistor or evaporator thermistor. The control logic 66 thencomputes the quotients (t_(REF) -t_(AMB)) divided by (t_(REF) +t_(AMB))and (t_(REF) -t_(EVAP)) divided by (t_(REF) +t_(EVAP)). These quotientsare proportional to the ambient and evaporator temperaturesrespectively. The division process cancels any errors due to capacitorleakage and line saturation voltage because all charge times areaffected in a similar manner and hence any error present disappears inthe division process. Both the ambient and evaporator temperatures areupdated several times per second.

Referring now to FIG. 6, the power supply is shown in block form andtriac circuits are illustrated in detail. The inputs to the triaccircuits are lines 110, 112, 114 and 116, which are output lines fromthe microcomputer 68, see FIG. 5, and which control the fan triacs 70,71 and 72, and the triacs 73 and 74 for the compressor 32. Opticalcouplers Q1, Q2, Q3, and Q4 isolate the microcomputer 68 from thetrigger circuitry for the fan 26 and the compressor 32. If any of the"A" output lines A9, A10, A11 or A12 are in a low state, then the signalover the corresponding line 110, 112, 114 or 116 will also be low,thereby allowing current to pass through and lighting the LED portion ofoptical couplers Q1-Q4. If one of these LED's is energized, thecorresponding optical couplers Q1-Q4 will gate into conduction one ofthe triacs 70, 71, 72 or 73 through corresponding resistors R17-R20,thereby allowing current to pass through the corresponding triac. Thetriacs 70, 71 and 72 are each connected to different motor winding tapsof a fan motor 76 connected in a conventional manner (not illustrated)so that energization of one of these triacs will cause the fan 26 tooperate at a particular speed. The triac 73 is connected to anothertriac 74 which in turn is connected to a winding of compressor motor 78.In the case of triac 70, 71 or 72, the fan will be activated in either alow, high or medium speed mode respectively. In the case of triac 73 theslave triac 74 will be gated by a signal through resistor R22 toenergize the compressor motor winding 78 over line 124.

Regulated power supply 118 connected to a source of electrical powerthrough lines 125 and 126 provides a source of constant DC voltage,V_(SS) over line 122 to the various components of the control. In theillustrated embodiment, V_(SS) is set to -9.0 volts. The ON/OFF switch60 is interposed between line 125 and power supply 118 to controlenergization of the various components of the system.

Referring now to FIGS. 8a-8d, a flow chart of the control program storedin the ROM 151 of microcomputer 68 is illustrated. System startup isinitiated at block 200 by depressing the ON/OFF switch 60. Thecompressor 32 and the fan 26 are then turned off by block 201. Theswitch state is set by block 202 to "AUTO" and the "POWER SAVER" isturned on, i.e. the fan speed will vary according to the differencebetween the ambient temperature and the set point temperature and thefan 26 will remain on for two minutes after the compressor cycles off.These conditions are set by block 202 so that the various components ofthe air conditioner are operating in a specific manner until the actualpanel state is determined. These conditions are stored in a panel stateregister (denoted PNL.ST.) of RAM 150 (see FIG. 5) and will continue toexist until updated by the microcomputer 68.

The compressor threshold temperature T_(C), which is the temperature atwhich the compressor cycles on, is set by block 203 at 2° F. above theset point temperature selected by the position of the slide switch 50. Ablock 204 now clears the two minute compressor timer 75 to begin anothertwo minute interval before which the compressor cannot be actuated.

In order to scan the slide switch 50 and the panel buttons 42-47 todetermine which slide switch position 50a-50h and which button 42-47 hasbeen selected, the control logic utilizes a scanning process. At block205 the 8-bit binary representation of the number 1 is assigned to avariable N which is stored in the RAM 150 and which represents theparticular "D" line being scanned at any particular moment. Each "D"line is assigned a particular bit of an 8-bit binary number such thatwhen a "1" is present in a particular bit, that "D" line is scanned atthat time. Line D0 is assigned the lowest order bit (i.e. the value00000001), line D1 is assigned the value 00000010 and so on, until D7,which is assigned the value 10000000. In this manner a line scanningcontrol is implemented by doubling the value of the variable N, therebyplacing a signal in the next highest order bit of the variable N andconsequently scanning the next "D" line in the series.

Decision block 206 determines if the particular touch panel switchcorresponding to the binary value of the variable N at that particularinstant has been pushed. If a signal is detected on input K2, indicatinga yes, control passes to a block 207 to determine whether the touchpanel switch has been closed for four cycles, or approximately 250milliseconds. If this is the case, block 208 stores the new panel statein the PNL.ST. register in the RAM 150. Block 209 energizes the LEDcorresponding to the particular button which has been pushed.

If block 206 determines that the particular touch panel switch has notbeen depressed or if block 207 determines that the button has not beenpushed for four cycles, control shifts to block 210 which determineswhether the slide switch 50 is in the particular position N. If theslide switch 50 is in the particular position corresponding to thebinary value of the variable N, then block 211 utilizes the switch stateposition to access a portion of memory in the ROM 151. The value storedin this position of memory is the set point temperature valuecorresponding to the switch state position selected by the user. Block211 retrieves this value and stores it in the SW.ST. register in the RAM150 for later use. If the switch is not in the position N, controlshifts to block 212 in which the variable N is updated by multiplyingits binary representation by two, thereby placing a signal on the next"D" line in the series.

A block 213, FIG. 8a, determines whether the variable N is less than orequal to the binary representation of 256, which in binaryrepresentation is 10000000; i.e. the block 213 determines whether "D"lines D0-D7 have all been scanned. If the variable N is less than orequal to 256, control shifts back to block 206 to continue the scanningsequence.

If N is greater than 256, indicating that all "D" lines have beenscanned, control passes to timing means, block 214, which times andstores the value for the reference resistance charge time t_(REF) in itsregister located in the RAM 150. Blocks 215 and 216 also comprise timingmeans and measure and store the temperature thermistor and evaporatorthermistor charge times, t_(AMB) and t_(EVAP) in their respectiveregisters in the RAM 150.

Block 217 performs a computation wherein the ambient and evaporatorthermistor charge times are converted to temperature values by means ofa linearization approximation program described later with reference toFIGS. 9a and 9b.

Block 218 recalls the contents of the SW.ST. register and computes thedifference between the ambient temperature value and the set pointtemperature value, as set by slide switch 50, and stores this value inthe T_(D) register in the RAM 150 (see FIG. 5). Similarly block 219stores the evaporator sensor temperature in the T_(E) register in theRAM 150.

Block 220 determines whether T_(D), which represents the differencebetween the ambient temperature and the set point temperature, isgreater than the threshold compressor value, or T_(C). If this is truethen block 221 stores a value of -2° F. in the register T_(C) in the RAM150. If T_(D) is not greater than T_(C), then block 222 stores a valueof +2° F. in the register T_(C).

A block 223 stores a value of 27° F. in a register T_(F) located in theRAM 150, which represents the point at which an unacceptable amount offrost has built up on the coils of the evaporator 24. Block 224determines whether the evaporator temperature is less than the valuestored as the variable T_(F). If this is not the case, block 226 thenrecalls the contents of the PNL.ST. register and determines whether the"POWER SAVER" mode is selected, and if it is, block 227 decides whetherthe two minute fan period has expired. If the two minute fan period hasnot expired, block 228 determines whether the variable T_(D) is lessthan 0° F., indicating that the ambient temperature is less than the setpoint temperature. If this is not the case, then block 229 determineswhether the variable T_(D) is less than T_(C), which represents thecompressor threshold temperature, which was set by either block 221 or222. If block 227 determines that the two minute period for theevaporator fan 26 is expired, then block 228 is skipped and controlpasses directly to block 229.

When T_(D) is not less than T_(C), control passes to block 230 whichdetermines whether the "FAN ONLY" button 44 has been pushed. If this isthe case then block 232 determines whether the "AUTO" button 42 has beenpushed by the user.

If block 224 determines that the temperature of the evaporator coils isless than the value of the variable T_(F), then block 225 stores a valueof 30° F. in the RAM 150 as the value of variable T_(F). From block 225control passes directly to block 232 which determines if the "AUTO"button 42 has been pushed. Similarly, if the "POWER SAVER" is not on, orif T_(D) is less than 0, or if T_(D) is less than T_(C), control passesto block 232.

If block 232 determines that the "AUTO" function has been selected bythe user, a search is performed for the interval within which the valueof the variable T_(D) falls. Block 233 determines if the variable T_(D)is greater than 0° F. If it is, then block 234 determines whether thevariable T_(D) is greater than 3°. If it is found that T_(D) is notgreater than 3°, indicating that the difference between the ambienttemperature and the set point temperature lies in an interval between 0°and 3°, block 235 energizes the line 114 of FIG. 6, thereby setting thefan speed to medium. If, however block 233 determines that T_(D) is notgreater than 0°, indicating that the ambient temperature is less thanthe set point temperature, block 236 energizes the line 110 of FIG. 6 toset the fan speed to low. If in the event that block 234 determines thatT_(D) is greater than 3°, indicating that the difference between theambient temperature and the set point temperature is greater than 3°,block 237 energizes the line 112 to set the fan 26 to high speed.

If block 232 determines that the user has not selected the "AUTO" mode,then block 238 determines whether the user has selected the "LOW" speedfan function. If this is the case then block 239 sets the fan speed tolow by energizing the line 110. If it is determined by block 238 thatthe user has not selected the "LOW" fan speed function then block 240determines whether the "HI" speed fan function has been selected. Ifthis is the case then block 241 sets the fan speed to high by energizingthe line 112. If block 240 determines that the "HI" speed function hasnot been selected, then control passes to block 242, which energizes theline 114 and thereby sets the fan speed to medium. Regardless of whichfan speed has been selected, control passes to block 243 which againdetermines whether the temperature is less than the value stored as thevariable T_(F) in the RAM 150.

If block 230 determines that the "FAN ONLY" mode is not selected thenblock 231 de-energizes the lines 110, 112 and 114 to turn the fan 26 offand control passes directly to block 243.

If it is found in block 243 that the evaporator temperature is not lessthan the variable T_(F), block 244 determines whether the two minutecompressor lockout period has expired. If it has, then block 245determines whether the "FAN ONLY" mode has been selected.

If block 245 determines that the "FAN ONLY" mode has not been selected,then block 246 determines whether the value of the variable T_(D) isless than the value of the variable T_(C). If this is true, indicatingthat the difference between the ambient temperature and the set pointtemperature is less than the compressor threshold temperature, thenblock 247 turns the compressor on by energizing the line 116 in FIG. 6.

If block 243 determines that the evaporator temperature is less than thevariable T_(F), indicating that an excessive amount of frost is formingon the evaporator 24, control shifts to block 248 which determineswhether the compressor 32 is on. Likewise, control shifts to block 248from block 244 if the two minute compressor lockout period has notexpired, or if it is deterined by block 245 that the "FAN ONLY" mode isselected, or if block 246 determines that the variable T_(D) is not lessthan the variable T_(C). If block 248 determines that the compressor 32is on, then block 249 turns the compressor 32 off by de-energizing theline 116 because a mode is selected in which the compressor 32 is notused. From block 249 control shifts back to block 204 to begin anothercontrol program execution.

If block 249 determines that the compressor 32 is not on, then block 250again decides whether the compressor lockout period is expired. If it isnot, block 251 advances the timer by one clock interval and control thenshifts to block 205 where another program execution is run. If block 250determines that the lockout period has expired, control passes directlyto block 205.

Referring now to FIGS. 9a and 9b, the thermistor linearization programas performed by block 217 of FIG. 8a is illustrated in detail. It isgenerally known by those skilled in the art that a thermistor'sresistance varies in a logarithmic manner with the temperature thethermistor is exposed to. The program makes a first order approximationof this logarithmic thermistor transfer function, and is virtually errorfree for a narrow range (approximately 20°). The program is implementedin the control logic 66 using double precision (8-bit) two'scomplementing arithmetic. No multplication or division is directlyrequired. The program determines both the ambient and evaporatortemperatures using the same steps. The approximation is analogouselectrically to putting a thermistor in a bridge circuit and usingconventional circuit analysis techniques to determine its resistance. Inaddition, the execution time is made constant by the use of timingdelays inserted in various portions of the program.

The approximation is made by computing two temporary sums (using theambient sensor as an example): S1, which is equal to (t_(REF) -t_(AMB));and S2, which equals (t_(REF) +t_(AMB)). S1 is multiplied by the binaryequivalent of 256 (or 10000000) and S2 is subtracted from it until theresult becomes negative. The number of total subtractions, stored in theRAM 150 as a temporary variable S3, is the end result and is also storedin the RAM 150 as the variable TEMP.

The approximation routine begins at block 300, where a temporary flagF1, which indicates when a result is computed, is set to zero and isstored in the RAM 150. Block 301 assigns a value of 0 to the temporary8-bit number stored in the register S3. Similarly, block 302 assigns avalue of 0 to another temporary 8-bit number stored in a register S4.Block 303 adds the reference resistance charge time t_(REF) and thethermistor resistance charge time t_(TH) (either t_(AMB) or t_(EVAP))and assigns this value to the temporary 8-bit variable stored in aregister S2.

Block 304 inverts the sign of the thermistor resistance charge time anda block 305 adds the inverted thermistor resistance charge time and thereference resistance charge time and stores the result in a register S1.

A decision is then made by block 306 whether the temporary number S1 isless than 0. If it is, block 307 assigns the number 1 to another 1-bitflag denoted F2 which indicates that S1 is negative. Then, block 308inverts the sign of the temporary number S1 to a positive sign. Block309 then performs the same sign inversion upon temporary number S2.

If block 306 determines that S1 is not less than 0, then block 310assigns a value of 0 to the temporary 1-bit flag F2, indicating that S1is positive. A delay is provided by block 311 so that the time requiredto go through the branch of the loop consisting of block 310 and block311 is the same as the time required to go through the portion of theloop consisting of blocks 307 and 308. Control from block 311 thenshifts to block 309.

Block 312 shifts the S1 register left one byte, leaving zeroes in the8-bits of the lower order byte. This is equivalent to multiplying S1 by256. Block 313 adds temporary numbers S1 and S2 and stores the result inthe register S1. This, in effect, is equivalent to subtracting S2 fromS1.

Block 314 determines whether the temporary 1-bit flag F1, used toindicate that the result has been found, is equal to 1. If it is not,indicating that the approximation is not complete, then block 315determines whether the temporary 8-bit number S1 is less than 0. If S1is less than 0, indicating that the last subtraction of S2 from S1 hasyielded a negative result, then block 316 stores the value of S3 (i.e.the total number of subtractions) in the TEMP register in the RAM 150,which represents the thermistor temperature.

Block 317 determines whether the temporary flag F2 is equal to 1. If itis, indicating that S1 was originally negative, then block 318 invertsthe sign of the variable TEMP. At this point a value of 1 is assigned tothe 1-bit result flag F1 by block 319.

If block 317 determines that F2 is not equal to 1, then control passesto a delay at block 320, the length of which is the same amount of timeit takes to operate in block 318.

If block 314 determines that F1 is equal to 1 or if block 315 determinesthat S1 is not less than 0 then control shifts to block 321, anotherdelay block, which corresponds to the time it takes to operate in blocks316, 317, 318 or 320 and 319. The purpose of each of the delay blocks isto assure that the time of execusion is constant regardless of the pathtaken within the control program.

Following block 319 or block 321 is a double precision addition routineby block 332 in which the value of S3 is incremented by one. Note thatthe value of TEMP will not be changed once it is determined that aresult has been found (i.e. F1 equals 1) because of the jump from block314 to block 321.

Block 323 determines whether the temporary 8-bit number S4 is greaterthan or equal to the binary equivalent of 256. If S4 is greater than orequal to 256 then block 234 terminates the approximation. If block 323determines that S4 is not greater than or equal to 256 then block 325increments the value of S4 by one and control passes back to block 313where the approximation program continues.

The final value of the temperature is stored in the RAM 150 as thevariable TEMP, which, because of the byte shift performed by block 312,is multiplied by 256. However, the values stored in the ROM 151 as theset point temperature values are similarly multiplied by 256, hence,this common factor "drops out" in subsequent operations in the mainprogram.

Once the ambient and evaporator temperatures are computed and stored,control shifts to block 218 of FIG. 8a, where the main program resumes.

I claim:
 1. A method of determining the temperature to which athermistor is exposed utilizing a capacitor, a reference resistor, meanscoupled to the capacitor and actuable to selectively charge thecapacitor through either of the reference resistor and the thermistor,means actuable to discharge the capacitor and timing means coupled tothe capacitor, comprising the steps:(a) actuating the charging means tocharge the capacitor through the reference resistor; (b) operating thetiming means to measure the length of time required to charge saidcapacitor to a predetermined level to obtain a reference charge time;(c) actuating the discharging means to discharge the capacitor; (d)actuating the charging means to charge said capacitor through saidthermistor; (e) operating the timing means to measure the length of timerequired to charge said capacitor to said predetermined level throughsaid thermistor to obtain a temperature charge time; and (f) computingthe difference between the reference charge time and the temperaturecharge time and dividing the difference by the sum of said referencecharge time and said temperature charge time to determine thetemperature to which said thermistor is exposed.
 2. The method of claim1 in which a second thermistor is exposed to a different temperature,the second thermistor being coupled to the charging means, the chargingmeans being actuable to selectively charge the capacitor through thesecond thermistor comprising the further steps of actuating the chargingmeans to charge said capacitor through said second thermistor, operatingthe timing means to measure said length of time required to charge thecapacitor to the predetermined level to derive a second temperaturecharge time, and computing the difference between the reference chargetime and the second charge time with the difference being divided by thesum of said reference charge time and said second charge time todetermine said different temperature.
 3. A method of determining thetemperature to which a thermistor is exposed in a temperature controlsystem for a space cooling device having an evaporator, an evaporatorfan, a compressor, control means including a microcomputer, a capacitorand a reference resistor, the microcomputer including charging meansselectively actuable to charge the capacitor through either of thereference resistor and the thermistor, discharging means actuable todischarge the capacitor and timing means coupled to the capacitor,comprising the steps:(a) actuating the charging means to charge thecapacitor through the reference resistor; (b) operating the timing meansto measure the length of time required to charge said capacitor to apredetermined level to obtain a reference charge time input for saidmicrocomputer; (c) actuating the discharging means to discharge thecapacitor; (d) actuating the charging means to charge said capacitorthrough said thermistor; (e) operating the timing means to measure thelength of time required to charge said capacitor to said predeterminedlevel through said thermistor to obtain a temperature charge time inputfor said microcomputer; and (f) computing in said microcomputer thedifference between the reference charge time and the temperature chargetime and dividing the difference by the sum of said reference chargetime and said temperature charge time to determine the temperature towhich said thermistor is exposed.
 4. An apparatus for determining thetemperature to which a thermistor is exposed, comprising:a capacitor; areference resistor coupled to the capacitor; first charging meanscoupled to the reference resistor and to the capacitor for charging saidcapacitor from a first predetermined charge level to a secondpredetermined charge level through said reference resistor; timing meanscoupled to the capacitor for measuring the length of time required tocharge said capacitor to said second predetermined level to obtain areference charge time; discharge means coupled to the capacitor fordischarging said capacitor to said first predetermined charge level;second charging means coupled to the thermistor and to the capacitor forcharging said capacitor to said second predetermined charge levelthrough said thermistor, said timing means measuring the length of timerequired to charge said capacitor to said second predetermined level toobtain a thermistor charge time; and computing means for computing thedifference between the reference charge time and the thermistor chargetime, the difference being divided by the sum of the reference chargetime and the thermistor charge time to determine the temperature towhich the thermistor is exposed.
 5. An apparatus for determining thetemperature to which a thermistor is exposed, comprising:a capacitorhaving one end coupled to a voltage source, and another end coupled tosaid thermistor; a reference resistor coupled to the other end of thecapacitor; sequential charging means coupled to the reference resistor,the thermistor and the capacitor for sequentially charging the capacitorto a predetermined value by the voltage source through the resistor andthe thermistor; timing means coupled to the capacitor for measuring thelengths of time required to sequentially charge the capacitor throughthe reference resistor and the thermistor to obtain a reference chargetime and a thermistor charge time, respectively; and computing means forcomputing the difference between the reference charge time and thethermistor charge time with the difference being divided by the sum ofthe reference charge time and the thermistor charge time to obtain avalue proportional to the temperature to which the thermistor isexposed, such value being substantially independent of leakage of thecapacitor. .Iadd.
 6. A method of determining the temperature to which atemperature sensor is exposed, comprising the steps of:providing areference resistor; providing a capacitor; providing means for chargingthe capacitor a predetermined amount sequentially through the referenceresistor and the temperature sensor; the capacitor by the predeterminedamount a first time through the reference resistor to obtain a firstindication of the time required to charge the capacitor by thepredetermined amount; charging the capacitor by the predetermined amounta second time through the temperature sensor to obtain a secondindication of the time required to charge the capacitor by thepredetermined amount; and comparing the first indication to the secondindication to determine the temperature to which the sensor is exposed..Iaddend. .Iadd.
 7. The method of claim 6, wherein the comparing stepincludes the step of computing the temperature from the first and secondindications in a microcomputer. .Iaddend. .Iadd.
 8. The method of claim6, wherein the step of charging the capacitor by the predeterminedamount a first time and the step of charging the capacitor by thepredetermined amount a second time each includes the step of increasingthe voltage on the capacitor from a first level to a second level..Iaddend. .Iadd.
 9. The method of claim 6, including the further step ofdischarging the capacitor after the first indication has been obtainedand before the capacitor is charged through the temperature sensor..Iaddend. .Iadd.10. The method of claim 6, in which a second temperaturesensor is exposed to a different temperature, including the furthersteps of charging the capacitor through the second temperature sensor toobtain a third indication of the time required to charge the capacitorby the certain amount and using the first and third indications toobtain a measure of the different temperature. .Iaddend. .Iadd.11. Amethod of determining the temperature to which a thermistor is exposedutilizing a capacitor, a reference resistor, means coupled to thecapacitor and actuable to selectively charge the capacitor througheither of the reference resistor and the thermistor, means actuable todischarge the capacitor and timing means coupled to the capacitor,comprising the steps of:(a) actuating the charging means to charge thecapacitor through the reference resistor; (b) operating the timing meansto measure the length of time required to charge said capacitor to apredetermined level to obtain a reference charge time; (c) actuating thedischarging means to discharge the capacitor; (d) actuating the chargingmeans to charge said capacitor through said thermistor; (e) operatingthe timing means to measure the length of time required to charge saidcapacitor to said predetermined level through said thermistor to obtaina temperature charge time; and (f) computing a value of the temperatureto which the thermistor is exposed using the reference charge time andthe temperature charge time whereby such value is independent of thecapacitance value of the capacitor. .Iaddend. .Iadd.12. A method ofdetermining the temperature to which a thermistor is exposed utilizing acapacitor, a reference resistor, means coupled to the capacitor andactuable to selectively charge the capacitor through either of thereference resistor and a thermistor, means actuable to discharge thecapacitor and timing means coupled to the capacitor, comprising thesteps of:(a) actuating the charging means to charge the capacitorthrough the reference resistor; (b) operating the timing means tomeasure the length of time required to charge said capacitor to apredetermined level to obtain a reference charge time; (c) actuating thedischarging means to discharge the capacitor; (d) actuating the chargingmeans to charge said capacitor through said thermistor; (e) operatingthe timing means to measure the length of time required to charge saidcapacitor to said predetermined level through said thermistor to obtaina temperature charge time; and (f) comparing the reference charge timeto the temperature charge time to determine the temperature to which thethermistor is exposed. .Iaddend. .Iadd.13. A method of determining thetemperature to which a thermistor is exposed in a temperature controlsystem for a space cooling device having an evaporator, an evaporatorfan, a compressor, control means including a microcomputer, a capacitorand a reference resistor, the microcomputer including charging meansselectively actuable to charge the capacitor through either of thereference resistor and the thermistor, discharging means actuable todischarge the capacitor and timing means coupled to the capacitor,comprising the steps of:(a) actuating the charging means to charge thecapacitor through the reference resistor; (b) operating the timing meansto measure the length of time required to charge said capacitor to apredetermined level to obtain a reference charge time input for saidmicrocomputer; (c) actuating the discharging means to discharge thecapacitor; (d) actuating the charging means to charge said capacitorthrough said thermistor; (e) operating the timing means to measure thelength of time required to charge said capacitor to said predeterminedlevel through said thermistor to obtain a temperature charge time inputfor said microcomputer; and (f) computing in said microcomputer a valueof the temperature to which said thermistor is exposed as a function ofthe reference charge time and the temperature charge time using analgorithm that is independent of the capacitance value of saidcapacitor. .Iaddend. .Iadd.14. A method of determining the temperatureto which a thermistor is exposed in a temperature control system for aspace cooling device having an evaporator, an evaporator fan, acompressor, control means including a microcomputer, a capacitor and areference resistor, the microcomputer including charging meansselectively actuable to charge the capacitor through either of thereference resistor and the thermistor, discharging means actuable todischarge the capacitor and timing means coupled to the capacitor,comprising the steps of:(a) actuating the charging means to charge thecapacitor through the reference resistor; (b) operating the timing meansto measure the length of time required to charge said capacitor to apredetermined level to obtain a reference charge time input for saidmicrocomputer; (c) actuating the discharging means to dishcharge thecapacitor; (d) actuating the charging means to charge said capacitorthrough said thermistor; (e) operating the timing means to measure thelength of time required to charge said capacitor to said predeterminedlevel through said thermistor to obtain a temperature charge time inputfor said microcomputer; and (f) comparing in said microcomputer thereference charge time to the temperature charge time to determine thetemperature to which the thermistor is exposed. .Iaddend. .Iadd.15. Amethod of determining the temperature to which a thermistor is exposedin a temperature control system for a space cooling device having anevaporator, an evaporator fan, a compressor, control means including amicrocomputer, a capacitor and a reference resistor, the microcomputerincluding charging means selectively actuable to charge the capacitorthrough either of the reference resistor and the thermistor, dischargingmeans actuable to discharge the capacitor and timing means coupled tothe capacitor, comprising the steps of:(a) actuating the charging meansto charge the capacitor through the reference resistor; (b) operatingthe timing means to measure the length of time required to charge saidcapacitor to a predetermined level to obtain a reference charge timeinput for said microcomputer; (c) actuating the discharging means todischarge the capacitor; (d) actuating the charging means to charge saidcapacitor through said thermistor; (e) operating the timing means tomeasure the length of time required to charge said capacitor to saidpredetermined level through said thermistor to obtain a temperaturecharge time input for said microcomputer; and (f) computing in saidmicrocomputer a value of the temperature to which said thermistor isexposed as a function of the reference charge time and the temperaturecharge time using an algorithm that is independent of the capacitancevalue of said capacitor and the voltage of said charging means..Iaddend. .Iadd.16. An apparatus for determining the temperature towhich a thermistor is exposed, comprising:a capacitor; a referenceresistor; sequential charging means coupled to the capacitor, thethermistor and the reference resistor for sequentially charging thecapacitor by a predetermined charge amount through the referenceresistor and the thermistor; timing means coupled to the capacitor formeasuring the length of time required to charge the capacitor by thepredetermined charge amount through the reference resistor and thethermistor to obtain a reference resistor charge time and a thermistorcharge time, respectively; and computing means for computing thetemperature to which the thermistor is exposed responsive to thereference charge time and the thermistor charge time. .Iaddend..Iadd.17. The apparatus of claim 16, wherein the computing meanscomprises a microcomputer. .Iaddend. .Iadd.18. The apparatus of claim16, wherein the sequential charging means includes a first seriescircuit comprising the reference resistor, the capacitor and a voltagesource and a second series circuit comprising the thermistor, thecapacitor and the voltage source. .Iaddend. .Iadd.19. The apparatus ofclaim 17, wherein the capacitor is coupled to an input of themicrocomputer and wherein the timing means senses the voltage developedat the microprocessor input. .Iaddend.